(PDF) The Eurasian Modern Pollen Database (EMPD), Version 2

Earth Syst. Sci. Data, 12, 2423–2445, 2020 https://doi.org/10.5194/essd-12-2423-2020 © Author(s) 2020. This work is distributed under the Creative Commons Attribution 4.0 License. The Eurasian Modern Pollen Database (EMPD), version 2 Basil A. S. Davis1 , Manuel Chevalier1 , Philipp Sommer1 , Vachel A. Carter2 , Walter Finsinger3 , Achille Mauri4 , Leanne N. Phelps1 , Marco Zanon5 , Roman Abegglen6 , Christine M. Åkesson7 , Francisca Alba-Sánchez8 , R. Scott Anderson9 , Tatiana G. Antipina10 , Juliana R. Atanassova11 , Ruth Beer6 , Nina I. Belyanina12 , Tatiana A. Blyakharchuk13 , Olga K. Borisova14 , Elissaveta Bozilova15 , Galina Bukreeva16 , M. Jane Bunting17 , Eleonora Clò18 , Daniele Colombaroli19 , Nathalie Combourieu-Nebout20 , Stéphanie Desprat21 , Federico Di Rita22 , Morteza Djamali23 , Kevin J. Edwards24 , Patricia L. Fall25 , Angelica Feurdean26 , William Fletcher27 , Assunta Florenzano18 , Giulia Furlanetto28 , Emna Gaceur29 , Arsenii T. Galimov10 , Mariusz Gałka30 , Iria García-Moreiras31 , Thomas Giesecke32 , Roxana Grindean33 , Maria A. Guido34 , Irina G. Gvozdeva35 , Ulrike Herzschuh36 , Kari L. Hjelle37 , Sergey Ivanov38 , Susanne Jahns39 , Vlasta Jankovska40 , Gonzalo Jiménez-Moreno41 , Monika Karpińska-Kołaczek42 , Ikuko Kitaba43 , Piotr Kołaczek42 , Elena G. Lapteva44 , Małgorzata Latałowa45 , Vincent Lebreton46 , Suzanne Leroy47 , Michelle Leydet48 , Darya A. Lopatina49 , José Antonio López-Sáez50 , André F. Lotter6 , Donatella Magri22 , Elena Marinova51 , Isabelle Matthias52 , Anastasia Mavridou53 , Anna Maria Mercuri18 , Jose Manuel Mesa-Fernández41 , Yuri A. Mikishin35 , Krystyna Milecka42 , Carlo Montanari54 , César Morales-Molino6 , Almut Mrotzek55 , Castor Muñoz Sobrino31 , Olga D. Naidina56 , Takeshi Nakagawa43 , Anne Birgitte Nielsen57 , Elena Y. Novenko58 , Sampson Panajiotidis53 , Nata K. Panova10 , Maria Papadopoulou53 , Heather S. Pardoe59 , Anna P˛edziszewska45 , Tatiana I. Petrenko35 , María J. Ramos-Román60 , Cesare Ravazzi28 , Manfred Rösch61 , Natalia Ryabogina38 , Silvia Sabariego Ruiz62 , J. Sakari Salonen60 , Tatyana V. Sapelko63 , James E. Schofield24 , Heikki Seppä60 , Lyudmila Shumilovskikh64 , Normunds Stivrins65 , Philipp Stojakowits66 , Helena Svobodova Svitavska67 , Joanna Świ˛eta-Musznicka45 , Ioan Tantau33 , Willy Tinner6 , Kazimierz Tobolski42, , Spassimir Tonkov15 , Margarita Tsakiridou53 , Verushka Valsecchi6 , Oksana G. Zanina68 , and Marcelina Zimny45 1 Institute of Earth Surface Dynamics IDYST, Faculté des Géosciences et l’Environnement, University of Lausanne, Batiment Géopolis, 1015, Lausanne, Switzerland 2 Department of Botany, Charles University, Benatska 2, Prague 2 128-01, Czech Republic 3 ISEM, CNRS, University of Montpellier, EPHE, IRD, Montpellier, France 4 European Commission Joint Research Centre, Directorate D – Sustainable Resources – Bio-Economy Unit, Via E. Fermi 2749, 21027 Ispra (VA), Italy 5 Institute of Pre- and Protohistoric Archaeology, Kiel University, Johanna-Mestorf-Str. 2–6, 24118 Kiel, Germany 6 Institute of Plant Sciences, University of Bern, Altenbergrain 21, Bern, Switzerland 7 Department of Geography and Sustainable Development, University of St Andrews, North Street, St Andrews, KY16 9AL, UK 8 Department of Botany, University of Granada, Avda. Fuente Nueva, 18071-Granada, Spain 9 School of Earth and Sustainability, 624 S. Knoles St., Ashust Building, Room A108, Flagstaff, AZ, USA 10 Botanical Garden of the Ural Branch of the Russian Academy of Sciences, 620144, Yekaterinburg, Russia 11 Biological Faculty, Department of Botany, Sofia University, 8 Dragan Tzankov bld., 1164 Sofia, Bulgaria 12 Pacific Institute of Geography FEB RAS, 7, Radio Street, 690042, Vladivostok, Russia 13 Institute of Monitoring of Climatic and Ecological Systems of Siberian Branch of Russian Academy of Sciences, Akademicheski ave. 10/3, 634055, Tomsk, Russia 14 Russian Academy of Sciences, Institute of Geography, Staromonetny lane 29, 119017, Moscow, Russia 15 Faculty of Biology, Laboratory of Palynology, Sofia University, 8 Dragan Tsankov blvd., 1164 Sofia, Bulgaria Published by Copernicus Publications. 2424 B. A. S. Davis et al.: The Eurasian Modern Pollen Database (EMPD), version 2 16 Siberian Branch of the Russian Academy of Sciences, c/o N. Ryabogina, Tyumen Scientific Centre SB RAS, Malygina st. 86, 625026, Tyumen, Russia 17 Department of Geography, Geology and Environment, University of Hull, Cottongham Road, Hull, HU67RX, UK 18 Laboratorio di Palinologia e Paleobotanica – Dipartimento Scienze della Vita, Università di Modena e Reggio Emilia, via Campi 287, 41125 Modena, Italy 19 Department of Geography, Royal Holloway University of London, Egham, Surrey TW20 0EX, UK 20 UMR 7194 – CNRS/MNHN, Dpt Homme et Environnement, Institut de Paléontologie Humaine 1, rue René Panhard, 75013 Paris, France 21 University of Bordeaux, EPOC UMR 5805, EPHE- PSL University, Allée Geoffroy St Hilaire, 33615 Pessac, France 22 Department of Environmental Biology, Sapienza University, Piazzale Aldo Moro, 5, Rome, Italy 23 Institut Méditerranéen de Biodiversité et d’Ecologie, Aix-Marseille Université – Campus Aix Technopôle de l’environnement Arbois Méditerranée Avenue Louis Philibert Bât Villemin – BP 80, 13545 Aix-en-Provence CEDEX 4, France 24 Departments of Geography and Environment and Archaeology, School of Geosciences, University of Aberdeen, Elphinstone Road, Aberdeen AB24 3UF, UK 25 Department of Geography & Earth Sciences, University of North Carolina, Charlotte, NC, USA 26 Department of Physical Geography, Goethe University, Altenhöferallee 1, 60438 Frankfurt am Main, Germany 27 Quaternary Environments and Geoarchaeology Group, Department of Geography, School of Environment, Education and Development, University of Manchester, Oxford Road, Manchester, M13 9PL, UK 28 CNR-IGAG, Laboratory of Palynology and Palaeoecology, Piazza della Scienza 1, 20126 Milan, Italy 29 GEOGLOB, Faculty of Sciences of Sfax, Route Soukra, BP. 802, 3038 Sfax, Tunisia 30 Faculty of Biology and Environmental Protection, Department of Geobotany and Plant Ecology, University of Łódź, Banacha Str. 12/16, 90-237 Łódź, Poland 31 Dpto. Bioloxía Vexetal e Ciencias do Solo, Facultade de Ciencias, Universidade de Vigo, 36310, Vigo, Spain 32 Department of Physical Geography, Faculty Geoscience, Utrecht University, P.O. Box 80115, 3508 TC, Utrecht, the Netherlands 33 Department of Geology, Babes-Bolyai University, Kogalniceanu Street, 400084, Cluj-Napoca, Romania 34 CIR-LASA – University of Genoa, Via Balbi, 6, 16126, Genoa, Italy, Italy 35 Far East Geological Institute FEB RAS, 159, Prospekt 100-letiya, 690022, Vladivostok, Russia 36 Alfred Wegener Institute Helmholtz Centre for Polar and Marine Research, Telegraphenberg A45, Potsdam, Germany 37 Department of Natural History, University Museum, University of Bergen, P.O. Box 7800, 5020 Bergen, Norway 38 Tyumen Scientific Centre SB RAS, Malygina st. 86, 625026, Tyumen, Russia 39 Brandenburgisches Landesamt für Denkmalpflege, Wünsdorfer Platz 4–5, 15806 Zossen OT Wünsdorf, Germany 40 Paleoecological Laboratory, Institute of Botany, Academy of the Sciences of the Czech Republic, Lidická 25/27, 602 00 BRNO, Czech Republic 41 Departamento de Estratigrafía y Paleontología, Universidad de Granada, Avda. Fuentenueva S/N, 18002 Granada, Spain 42 Laboratory of Wetland Ecology and Monitoring, Adam Mickiewicz University, B. Krygowskiego 10/247, 61-680 Poznań, Poland 43 Research Centre for Palaeoclimatology, Ritsumeikan University, 1-1-1 Noji-Higashi, Kusatsu, Shiga 525-8577, Japan 44 Laboratory of Paleoecology, Institute of Plant and Animal Ecology of the Ural Branch of the Russian Academy of Sciences, 8 Matra str., 202, 620144, Yekaterinburg, Russia 45 Department of Plant Ecology, Laboratory of Palaeoecology & Archaeobotanyul, University of Gdańsk, Wita Stwosza 59, 80-308 Gdańsk, Poland 46 CNRS/Muséum National d’Histoire Naturelle, UMR 7194 – Institut de Paléontologie Humaine 1, rue René Panhard, 75013 Paris, France 47 AMU-LAMPEA, Aix Marseille Univ, CNRS, Minist Culture, LAMPEA, UMR 7269, 5 rue du Château de l’Horloge, 13094, Aix-en-Provence, France Earth Syst. Sci. Data, 12, 2423–2445, 2020 https://doi.org/10.5194/essd-12-2423-2020 B. A. S. Davis et al.: The Eurasian Modern Pollen Database (EMPD), version 2 2425 48 Aix Marseille Univ, Avignon Université, CNRS, IRD, IMBE, Europôle Arbois, Aix-en-Provence, France 49 Laboratory of Stratigraphy and Paleogeography of oceans Geological Institute Russian Academy of Sciences, Pyzevskii per., 119017, Moscow, Russia 50 Instituto de Historia-CSIC, Albasanz 26–28, 28037 Madrid, Spain 51 State Office for Cultural Heritage Baden Württemberg, Laboratory for Archaeobotany, Fischersteig 9, 78343 Hemmenhofen, Germany 52 Campus Institute Data Science, Göttingen, Germany 53 Laboratory of Forest Botany-Geobotany, Faculty of Forestry and Natural Environment, Aristotle University of Thessaloniki, Thessaloniki, Greece 54 University of Genoa, DISTAV – Corso Europa, 26, Genoa, Italy 55 Institute of Botany and Landscape Ecology, University of Greifswald, Soldmannstr. 15, 17487 Greifswald, Germany 56 Geological Institute RAS, Pyzhevsky 7, 119017, Moscow, Russia 57 Lund University, Sölvegatan 12, 66362 Lund, Sweden 58 Faculty of geography, Department of Physical Geography and Landscape Science, Lomonosov Moscow State University, Leninskiye gory, 1., 119991, Moscow, Russia 59 National Museum Wales, Cathays Park, Cardiff CF10 3NP, UK 60 Department of Geosciences and Geography, University of Helsinki, P.O. Box 64 (Gustaf Hällströmin katu 2), F00014, Helsinki, Finland 61 Department of Philosophy, Universität Heidelberg, Sandgasse 7, 69117 Heidelberg, Germany 62 Dept. de Biodiversidad, Ecología y Evolución, Universidad Complutense de Madrid, Ciudad Universitaria 28040, Madrid, Spain 63 Institute of Limnology, RAS, 9, Sevastyanova st., 196105, St. Petersburg, Russia 64 Department of Palynology and Climate Dynamics, University of Göttingen, Wilhelm-Weber-Str. 2a, 37073 Göttingen, Germany 65 Department of Geography, University of Latvia, Jelgavas str. 1, 1004, Riga, Latvia 66 Institute of Geography, University of Augsburg, Alter Postweg 118, 86159 Augsburg, Germany 67 Institute of Botany, Czech Academy of Sciences, Zámek 1, 252 43 Pruhonice, Czech Republic 68 RAS, Laboratory of Soil Cryology, Institute of Physico-Chemical and Biological Problems in Soil Science, Moscow region, Institutskaya 2, 142290, Pushchino, Russia deceased Correspondence: Basil A. S. Davis (

) Received: 21 January 2020 – Discussion started: 24 February 2020 Revised: 15 May 2020 – Accepted: 7 August 2020 – Published: 9 October 2020 Abstract. The Eurasian (née European) Modern Pollen Database (EMPD) was established in 2013 to provide a public database of high-quality modern pollen surface samples to help support studies of past climate, land cover, and land use using fossil pollen. The EMPD is part of, and complementary to, the European Pollen Database (EPD) which contains data on fossil pollen found in Late Quaternary sedimentary archives throughout the Eurasian region. The EPD is in turn part of the rapidly growing Neotoma database, which is now the primary home for global palaeoecological data. This paper describes version 2 of the EMPD in which the number of samples held in the database has been increased by 60 % from 4826 to 8134. Much of the improvement in data coverage has come from northern Asia, and the database has consequently been renamed the Eurasian Modern Pollen Database to reflect this geographical enlargement. The EMPD can be viewed online using a dedicated map-based viewer at https://empd2.github.io and downloaded in a variety of file formats at https: //doi.pangaea.de/10.1594/PANGAEA.909130 (Chevalier et al., 2019). https://doi.org/10.5194/essd-12-2423-2020 Earth Syst. Sci. Data, 12, 2423–2445, 2020 2426 B. A. S. Davis et al.: The Eurasian Modern Pollen Database (EMPD), version 2 1 Introduction dardised database of modern pollen samples was required, comparable to the European Pollen Database (EPD) for fos- Modern pollen samples provide an essential source of infor- sil pollen samples and reflecting the same open-access and mation for interpreting and understanding the fossil pollen community-based principles. record, which in turn provides one of the most important spa- The Eurasian (née European) Modern Pollen Database tially resolved sources of information on Quaternary vegeta- (EMPD) was therefore established in 2013 as a complement tion and climate. We use the term “fossil pollen” here as it to the European Pollen Database (EPD) for fossil pollen is commonly used in the Quaternary sciences. The fossils in (Davis et al., 2013). The first version of the EMPD (refer- this sense can more accurately be described as sub-fossils enced herein as the EMPD1) contained almost 5000 samples, since they have usually only undergone limited (if any) post- submitted by over 40 individuals and research groups from deposition mineralisation, while pollen is taken to include all over Europe. Over the last 6 years more data have contin- many spores as well as the pollen from flowering plants. ued to be submitted, and additional efforts have been made Fossil pollen can be found preserved in sediments in lakes to incorporate more data held in open data repositories such and bogs and other anaerobic environments throughout the as PANGAEA and made available as a supplement in pub- Eurasian region extending back throughout the Quaternary. lished studies. This paper documents the first update to the Modern pollen is simply the component of that fossil record EMPD (referenced herein as EMPD2), in which the number found in the last 100–150 years, most often in the surface lay- of samples stored in the database has increased by around ers of lake and bog sediments, but also including comparable 60 %. collectors of pollen such as moss polsters. The EMPD remains the only open-access database of Davis et al. (2013) include a comprehensive introduction modern pollen samples covering the Eurasian continent. to the different scientific uses of modern pollen samples. Smaller compilations of modern pollen samples exist for Modern pollen samples have been used to interpret many dif- some regions, but these generally have limitations in terms ferent environmental processes, such as past changes in land of some or all of the following: (1) the extent of meta- cover, land use, and human impact; the impact on vegetation data provided, (2) the completeness of the taxa assemblage, of past edaphic and hydroseral changes; and the effects of (3) the standardisation of taxa nomenclature and hierarchy past changes in fire, pests, and disease on vegetation. Modern with respect to the EPD, (4) the inclusion of digitised rather samples have also been used to understand taphonomic prob- than original raw count data, (5) the inclusion of percent- lems with regard to pollen transport, deposition, and preser- ages rather than raw counts, (6) information about the orig- vation. One of the early motivations for establishing large inal source of the data and the analyst, and in some cases, modern pollen datasets and one that still remains important (7) limitations to public access. Importantly, all of these as- is their use as calibration “training sets” for the quantitative pects limit their compatibility with the EPD, where compat- reconstruction of past climate. This approach has also more ibility with the EPD is one of the primary objectives of the recently been adapted to quantitative reconstructions of land EMPD. The EMPD contains only the original raw count data cover, where a similar modelling approach to climate recon- (no percentage data) for the complete pollen assemblage. The struction is applied to determine, for instance, forest cover. EMPD also contains comprehensive and standardised meta- Similarly, modern samples have also been used to establish data about the pollen sample location, the landscape and veg- and model the relationship between vegetation and pollen as- etation environment from which it was collected, the way it semblages based on the different pollen productivity of dif- was collected, the year that it was collected, and who col- ferent taxa and thereby provide quantitative estimates of past lected and analysed the sample and where it was published. vegetation composition in a landscape from records of fossil The EMPD has no formal spatial domain, but in general pollen. it covers the same geographic region as the EPD. This has Historically, modern pollen data were often gathered di- traditionally been the Palearctic vegetation region of Eurasia rectly for a particular research project, but the data were excluding China, which has established its own semi-private rarely shared and if published often in grey literature such regional database. As well as the terrestrial Eurasian land- as a thesis, report, or monograph. Efforts to develop larger mass and associated islands, it also includes marine samples datasets at continental scales were pioneered in the 1990s, from coastal margins and enclosed seas. Increasingly how- primarily by research groups looking to use these datasets as ever these geographical administrative boundaries have be- calibration datasets for quantitative climate reconstruction. come blurred as regional pollen databases become integrated Development however was haphazard, and the datasets had into the global Neotoma Palaeoecology Database (Williams a reputation for being poorly documented and quality con- et al., 2018), hereafter referred to as “Neotoma”. While re- trolled, often containing duplicates, digitised data (not orig- gional databases such as the EPD will outwardly retain their inal raw counts), uncertain taxonomic standardisation, poor identity within Neotoma, internally the data will be com- geolocation information, and loose definitions of “modern” pletely integrated at a global level. It is also planned that the that could embrace as much as the last 500 years. It be- EMPD will become integrated into Neotoma in the near fu- came increasingly clear that a quality controlled and stan- ture, and with this in mind, the EMPD2 also includes data Earth Syst. Sci. Data, 12, 2423–2445, 2020 https://doi.org/10.5194/essd-12-2423-2020 B. A. S. Davis et al.: The Eurasian Modern Pollen Database (EMPD), version 2 2427 Table 1. List of metadata fields used in the EMPD. Sample name Original authors’ sample name Free text Sigle EMPD unique sample identifier Assigned Site name Original authors’ site name Free text Country Country where the site is located List Longitude Longitude in decimal degrees Numeric Latitude Latitude in decimal degrees Numeric Elevation Elevation in metres above sea level Numeric Location Reliability estimate of the accuracy of the geolocation information List Location notes Notes about the site location Free text Area of site Site size in hectares Numeric Sample context Physical environment of the site List Site description Notes about the physical context of the site Free text Vegetation Description notes about the surrounding vegetation Free text Sample type The type of material or sediment sampled List Sample method The method used to obtain the pollen sample List Age BP The age of the sample BP Numeric Age uncertainty The age uncertainty associated with the sample List Notes General notes concerning the sample and site Free text Publications 1–4 Any publications associated with the sample Free text Worker role The name of the responsible person or analyst Free text Worker details Address and contact details for this person Free text from outside of the traditional EPD region on the basis that it more comparable with the time typically represented in a fos- represented the most expeditious route to making these data sil pollen sample taken from a sediment core. publicly available within Neotoma. Consequently, this sec- Like the EPD, the EMPD only includes raw count data ond version of the EMPD includes not only data from Eu- representing the full pollen assemblage, and it does not con- rope and northern Asia, but also data from Greenland, India, tain percentage data or truncated or summary assemblages. China, and North Africa. Percentages are excluded because their calculation can vary from author to author, and therefore unlike raw count data it is not always possible to directly compare different samples from different sources with percentage data. This is an im- 2 Methods portant data quality criteria, but it has led to the exclusion of some large regional modern pollen datasets that have been Details about the structure and metadata of the database have recently published. This is discussed in the next section. already been described in detail by Davis et al. (2013). The Modern pollen samples have been gathered from a variety list of metadata fields is shown in Table 1. We also include of depositional environments, and the type of environment is climate and vegetation data for each sample location. The recorded for 75 % of the samples in the database. The most climate data include mean monthly, seasonal, and annual common environments are moss polsters (31 %), soil (21 %), temperature and precipitation climatology from WorldClim2 and lake sediments (19 %). (Fick and Hijmans, 2017). The climate was assigned accord- ing to the nearest grid point within the 30 s (approximately 1 km2 ) resolution of the WorldClim2 grid. The vegetation data include realm, biome, and ecoregion, taken from Ol- 2.1 Data sources son et al. (2001). Note that all samples have been assigned a biome, including marine samples. The biome assigned to The pollen data for the latest update of the EMPD have marine samples was based on the nearest point of land to the come from a diverse range of sources, but mainly submis- sample. No climate has been assigned to marine samples. sions from individual researchers and research groups. Most The protocol for the database follows that of the European of this has been the result of published research (Table 2), Pollen Database, with some additions. The EMPD only in- but we also include unpublished data. Additional pollen data cludes samples younger than 200 BP, and with a sampling have come from open-access sources such as the PANGAEA resolution comparable with the fossil pollen in the EPD. For data archive and data supplements to publications, as well as instance, the EMPD does not include pollen trap data gath- new fossil pollen data submitted to the EPD and Neotoma ered at monthly or annual resolution, but it does accept trap since EMPD1 where the sample age of a sediment core top data averaged over a period of at least 10 years, which is fulfils the requirements of a modern pollen sample. https://doi.org/10.5194/essd-12-2423-2020 Earth Syst. Sci. Data, 12, 2423–2445, 2020 2428 B. A. S. Davis et al.: The Eurasian Modern Pollen Database (EMPD), version 2 Table 2. List of data submitted to the EMPD2 by country. Sample(s) Country Contributor(s) Publication(s) 3 Belarus Binney, H. Binney et al. (2016, 2017) 41 Bulgaria Atanassova, J., Lazarova, M., Tonkov, Atanassova (2007); Lazarova et al. (2006) S. 33 China, People’s Binney, H. Binney et al. (2016, 2017) Republic of 56 Cyprus Fall, P. Fall (2012) 47 Czech Republic Svobodova Svitavska, H. Helena (2004); Pardoe et al. (2010); Svobodová (1989, 1997, 2002); Svobodová et al. (2001) 1 Finland Stivrins, N. Stivrins et al. (2017b) 4 France Leroy, S. 4 Georgia Binney, H. Binney et al. (2016, 2017) 85 Germany Giesecke, T., Matthias, I., Mrotzek, A., Lechterbeck (2001); Matthias et al. (2012, 2015); Rösch, M., Stojakowits, P. Mrotzek et al. (2017); Rösch et al. (2017); Rösch (2009, 2012, 2013, 2018); Rösch and Lechterbeck (2016); Rösch and Tserendorj (2011a, b); Rösch and Wick (2019); Stojakowits (2015) 76 Greece Jahns, S., López Sáez, J., Mavridou, Glais et al. (2016); Jahns (1992); Pardoe et al. (2010) A., Panajiotidis, S., Papadopoulou, M., Tsakiridou, M. 64 Greenland Edwards, K., Schofield, J. Schofield et al. (2007) 4 Iceland Hallsdottir, M., Stivrins, N. 16 India Demske, D., Tarasov, P. Leipe et al. (2014) 64 Iran, Islamic Djamali, M., Leroy, S., Ramezani, E. Djamali et al. (2009); Haghani et al. (2016); Leroy et al. Republic of (2011, 2018); Ramezani et al. (2013) 243 Italy Accorsi, C., Badino, F., Champvillair, Abbate, 1981; Finsinger et al. (2007, 2010); Florenzano E., Clò, E., Colombaroli, D., Di Rita, F., et al. (2017); Florenzano and Mercuri (2018); Furlan- Finsinger, W., Florenzano, A., Furlan- etto et al. (2019); Guido et al., 1992; Joannin et al. etto, G., Greggio, B., Joannin, S., Leroy, (2012); Margaritelli et al. (2016); Mercuri et al. (2012); S., Lotter, A., Magri, D., Mercuri, A., Montali et al. (2006); Montanari and Guido (1994); Rat- Montanari, C., Rattighieri, E., Ravazzi, tighieri et al. (2010) (2012); Di Rita et al. (2011, 2018a, C., Suanno, C., Tinner, W., Valsecchi, b); Di Rita and Magri (2009) V. 84 Japan Kitaba, I., Leipe, C., Nakagawa, T., Leipe et al. (2018) Watanabe, M. 5 Kazakhstan Duryagina, N., Naidina, O., Naidina and Richards (2018); Nepomilueva, N. Nepomilueva and Duryagin (1990) 43 Kyrgyzstan Beer, R., Morales-Molino, C., Tinner, Beer et al. (2007) W. 10 Latvia Stivrins, N. Feurdean et al. (2017); Grudzinska et al. (2017); Stivrins et al. (2014, 2015a, b, 2016b, a, 2017a); Veski et al. (2012) 120 Morocco Alba-Sánchez, F., Fletcher, W., Bell and Fletcher (2016) Sabariego Ruiz, S. Earth Syst. Sci. Data, 12, 2423–2445, 2020 https://doi.org/10.5194/essd-12-2423-2020 B. A. S. Davis et al.: The Eurasian Modern Pollen Database (EMPD), version 2 2429 Table 2. Continued. Sample(s) Country Contributor(s) Publication(s) 231 Norway Hjelle, K., Pardoe, H. Caseldine and Pardoe (1994); Hjelle et al. (2015); Hjelle and Sugita (2012); Mehl and Hjelle (2016); Par- doe, (1992, 2001, 2006, 2014) 115 Poland Gałka, M., Karpińska-Kołaczek, M., Gałka et al. (2014, 2017); Milecka et al. (2017); Pardoe Kołaczek, P., Latałowa, M., Milecka, et al. (2010); P˛edziszewska (2008); P˛edziszewska et al. K., P˛edziszewska, A., Tobolski, K., (2015); P˛edziszewska and Latałowa (2016); Pidek et al. Zimny, M., Świ˛eta-Musznicka, J. (2010) 12 Portugal Fletcher, W. Fletcher (2005) 17 Romania Feurdean, A., Grindean, R., Tantau, I. Fărcaş and Tanţău (2012); Feurdean et al. (2009, 2013, 2015); Feurdean and Willis (2008a, b); Grindean et al. (2014, 2015); Tanţău et al. (2014a, b, 2009, 2011) 1883 Russian Antipina, T., Aseev, N., Belyanina, Antipina et al. (2014, 2016); Aseev, 1959; Binney et Federation N., Binney, H., Blyakharchuk, T., al. (2016, 2017); Blyakharchuk et al. (2007, 2019); Borisova, O., Bukreeva, G., Duryagin, Blyakharchuk and Chernova (2013); Borisova et al. D., Duryagina, N., Dyuzhova (Kras- (2011); Bukreeva et al., 1986; Duguay et al. (2012); norutskaya), K., Erokhin, N., Feur- Hijmans et al. (2005); Ivanov and Ryabogina (2004); dean, A., Galimov, A., Golubeva, Y., Klemm et al. (2013, 2016); Kosintsev et al. (2010); Gvozdeva, I., Herzschuh, U., Ivanov, S., Lapteva (2009); Lapteva et al. (2013); Lapteva (2013); Karaulova, L., Khaymusova, N., Khizh- Lapteva et al. (2017); Lapteva and Korona (2012); nyak, N., Kremenetsky, N., Lapteva, E., Larin and Ryabogina (2006); Lopatina and Zanina Lopatina, D., Makovsky, N., Makovsky, (2016); Lychagina et al. (2013); Makovsky and Panova, V., Marchenko-Vagapova, T., Marieva, 1978; Matishov et al. (2011); Matveev et al., 1997; N., Matishov, G., Mikishin, Y., Müller, Matveeva et al. (2003); Mikishin and Gvozdeva (2009, S., Naidina, O., Nepomilueva, N., 2012); Müller et al. (2010); Naidina and Richards Niemeyer, B., Nikiforova, L., Nosevich, (2018); Nepomilueva and Duryagin, 1990; Niemeyer E., Nosova, M., Novenko, E., Panova, et al. (2017); Nikiforova (1978); Novenko et al. N., Panova, N., Petrenko, T., Pis- (2011, 2014, 2017); Panova, 1981; Panova et al., areva, V., Pisareva, N., Plotnikova, N., (1996, 2010, 2008); Panova and Korotkovskaya (1990); Ryabogina, N., Salonen, J., Sapelko, T., Panova and Makowski (1979); Petrenko et al. (2009); Semochkina, T., Seppä, H., Severova, Poshekhonova et al. (2008); Ryabogina and Orlova E., Stivrins, N., Surova, N., Troitskiy, (2002); Salonen et al. (2011, 2012); Sapelko and No- N., Vlasta Jankovska, N., Volkova, O., sevich (2013); Shavnin et al. (2006); Stivrins et al. Yankovska, N., Zanina, O., Zelikson, (2017b); Surova and Troitsky, 1971; Zakh (1997) E., Zhuykova, I. 134 Spain Alba-Sánchez, F., Anderson, R., Anderson et al. (2011); García-Moreiras et al. (2015); García-Moreiras, I., Jiménez-Moreno, Jiménez-Moreno et al. (2013); Jiménez-Moreno and G., Leroy, S., López-Sáez, J.A., Mesa- Anderson (2012); Leroy, 1990; Mesa-Fernández et al. Fernández, J., Morales-Molino, C., (2018); Morales-Molino et al. (2017a, b, 2018, 2011, Muñoz Sobrino, C., Ramos-Román, 2013); Morales-Molino and García-Antón (2014); M., Sabariego Ruiz, S. Muñoz Sobrino et al. (2014); Ramos-Román et al. (2016,2018) 4 Sweden Nielsen, A., Åkesson, C. Åkesson et al. (2015); Ning et al. (2018) 29 Tunisia Desprat, S., Gaceur, E. Gaceur et al. (2017) 31 Turkey Shumilovskikh, L. 2 Ukraine Binney, H., Borisova, O. Binney et al. (2016, 2017) 18 United Bunting, M. Kingdom https://doi.org/10.5194/essd-12-2423-2020 Earth Syst. Sci. Data, 12, 2423–2445, 2020 2430 B. A. S. Davis et al.: The Eurasian Modern Pollen Database (EMPD), version 2 Some large independent surface sample datasets covering Table 3. Web addresses for pollen databases mentioned in the text. the Eurasian region have been published and made available Last access of all URLs: 20 January 2020. since EMPD1, most notably Binney et al. (2017), Marinova et al. (2018), and Herzschuh et al. (2019). Both Binney et Eurasian Modern Pollen Database (EMPD) al. (2017) and Marinova et al. (2018) already include a large Viewer: https://empd2.github.io/?branch=master amount of data from the EPD and EMPD1, but also data Data link: https://epdweblog.org/ that have not been publicly released before. This includes european-modern-pollen-database/ “heritage” data from earlier studies such as the Biome6000 European Pollen Database (EPD) project Prentice and Webb, 1998) and PAIN project (Bigelow et al., 2003). These heritage data are mostly composed of per- Viewer: http://www.europeanpollendatabase.net/ centages, at least some (unknown part) of which have been fpd-epd/bibli.do digitised, and whose origins, selection criteria, and context Data link: https://epdweblog.org/epd_data/ are rarely documented. Another problem with these heritage Neotoma Paleoecology Database (NEOTOMA) data apart from the limited metadata is the loose definition of a “modern sample” in these early projects, being defined in Viewer: https://apps.neotomadb.org/explorer/ Data link: https://www.neotomadb.org/data both PAIN and Biome6000 as anything younger than 500 BP. Unfortunately, the age criteria for selecting individual sam- African Pollen Database (APD) ples were not recorded when the datasets were compiled. Viewer: http://fpd.sedoo.fr/fpd/bibli.do These problems also extend to the recent release of data Data link: http://fpd.sedoo.fr/fpd/english.do by Herzschuh et al. (2019) from China and Mongolia. These data represent most of the modern pollen data held in the Pangaea Data Archive (PANGAEA) Chinese Pollen Database (CPD) (Ni et al., 2010; Zheng et Viewer: https://www.pangaea.de al., 2014). The Herzschuh et al. (2019) dataset includes 2559 Data link: https://doi.pangaea.de/10.1594/PANGAEA. modern pollen samples and is of major importance as the 909130 first significant amount of publicly available data from this region. However, the data are only provided as percentages based on a summary of the taxa from each sample and also include digitised data. We were therefore unable to include it els of metadata. All of these files had to be processed and a in the EMPD2. The Herzschuh et al. (2019) data are available variety of quality control checks made before entry into the from PANGAEA, along with the Tarasov et al. (2011) dataset database (see also Davis et al., 2013). of 798 samples mainly from Japan and eastern Russia, which Figure 1 shows the steps taken in processing and quality- are also provided as percentages for a limited selection of controlling the data. On receipt from the contributor, the data taxa. We hope that the raw count data for the full assemblage were entered into one of two standardised file formats ac- will be made available in the near future. cording to whether they were pollen data or the associated Other regional pollen databases that overlap with the metadata. Each of the two different types of data was then EMPD include the Indian Pollen Database (IPD) and the subject to a series of quality control checks to make sure they African Pollen Database (APD). The IPD is still under de- did not contain errors and that they conformed to data proto- velopment and is not publicly accessible, but it includes both cols. For instance, values in numerical fields in the metadata fossil and modern pollen samples from the Indian subconti- (shown in Table 1) had to fall within realistic boundaries ex- nent (Krishnamurthy and Gaillard, 2011). The EMPD also pected for that field, such as for latitude, longitude, and alti- includes samples from North Africa, which overlaps with tude. Also, it had to be checked that controlled fields based the APD (Vincens et al., 2007). Fossil pollen data from the on selection from a list of acceptable classes did not contain APD are available as individual files and as a partially com- assignment errors, such as country name. Any missing en- plete paradox database from the APD website (Table 3), but tries were referred back to the contributor for completion, or the status of the modern pollen data held within the APD else were completed from the original publication or other (Gajewski et al., 2002) remains somewhat unclear, since information source where available. these data have not been made publicly available. At present One of the most time-consuming tasks with the pollen data the APD is being integrated into Neotoma, and it is hoped was to ensure standardisation of the original taxon names that once this is completed the modern pollen data from submitted by the contributor. These all had to be checked Africa will become more freely available. for language, typographical errors, and other issues and then assigned an internationally accepted taxa name according 2.2 Data processing to the EPD common taxa “p_vars” table. If the name did not exist in the EPD taxa table it was checked (using http: As with the EMPD1, the data submitted to the EMPD2 have //www.theplantlist.org/, last access: 20 January 2020) that it come in a wide variety of data formats and with varying lev- was spelled correctly and was not a synonym. It was then Earth Syst. Sci. Data, 12, 2423–2445, 2020 https://doi.org/10.5194/essd-12-2423-2020 B. A. S. Davis et al.: The Eurasian Modern Pollen Database (EMPD), version 2 2431 checked against the Neotoma pollen taxa table and assigned names, address details, and data references across different the Neotoma-accepted taxa name if there was a match. If it datasets submitted to the database. was not in the Neotoma taxa table, and it was established After the data had passed these database checks, each con- to be a genuine taxa name, then it was added to the EMPD tributor was then asked to look again at their data as they taxa table as a new taxon. Note that although the EMPD is were now stored in the database. Contributors were able to designed to be as compatible with the EPD as possible, the do this using the online data viewer, which provided an intu- EMPD and EPD do not have a common taxa list, and the itive interface to the database that could be navigated without EMPD has many more taxa than appear in the EPD. any prior experience of database systems. Locations for each The accepted names for the fossil data in the EPD or site/sample could be checked using the viewer map interface, Neotoma should be directly compatible with the accepted pollen data could be checked using a graphical (histogram) names in the EMPD, but some caution needs to be applied display, and metadata could be checked using a table view of in integrating the two datasets since the EMPD contains ad- all of the metadata fields. Any issues highlighted by the con- ditional accepted names that do not occur in the EPD or tributors were then corrected in the database. It was only af- Neotoma. Where possible the EMPD assignment of accepted ter completing these final contributor checks that the EMPD2 names respects the taxonomic resolution of the EPD- and database was deemed suitable for public release. Neotoma-accepted names. This means that where a new orig- As well as adding new data, we also undertook a short inal taxa name is submitted to the EMPD that does not al- review of the data in the original EMPD1. A cross-check be- ready occur in the existing databases, it is assigned the EPD- tween the country attributed to a site and the actual country or Neotoma-accepted name according to the existing taxo- where the site was located revealed that around 20 sites had nomic hierarchy. For example, if the new submitted original either the wrong location or wrong country code. The geolo- taxa name is a new species that does not occur in the EPD cation data for around 250 samples in Morocco in EMPD1 or Neotoma, and there is an existing accepted name at genus have now been removed and placed in the information field. level, then the new species name is assigned the accepted These were all highlighted in EMPD1 as having intractable name at the genus level. The assignment of accepted names geolocation errors (Davis et al., 2013), and it was felt that by is complicated because it requires an appreciation of differ- removing the corrupt information from the geolocation field ences in pollen morphology and of the reliability of iden- it would discourage their accidental use. In compensation the tification, which can vary given the differences in skill and EMPD2 now includes new high-quality data from Morocco experience of the different analysts who contribute to the (see next section). database. In addition, there are also important geographical considerations to take into account. For instance, the EMPD 3 Results conforms to the EPD-accepted names but these are heavily European orientated, while the EMPD has much more data 3.1 Spatial sampling from regions such as eastern Asia where some of the ac- cepted names are not strictly appropriate. However, in all The amount of data in the database has increased by 60 %, cases we have retained in the EMPD all of the original taxa and the EMPD2 now holds 8134 samples compared to 4826 names as they were submitted by the original contributor af- samples in the EMPD1. The country that has experienced ter cleaning for typographical errors. the largest increase in samples is Russia, which has gained In the process of updating the EMPD we have harmonised 2274 more samples on top of the 379 samples already in the as much as possible the taxa names in the EMPD with those EMPD1 (Fig. 1). Other significant improvements in data cov- found in the current EPD, including those names previously erage have been made in Italy, Norway, and Spain, while data in the EMPD1 that have since been included in the EPD. are available for the first time from other countries such as When both the EPD and EMPD are included in the Neotoma Japan, Cyprus, and Kyrgyzstan. The increase in data from database, then all of the taxa will exist in a single standard- Russia reflects a general improvement in data coverage in ised taxa table consisting of all of the taxa in all of the EMPD2 from eastern Europe across to Asia (Fig. 2), prompt- databases. ing a renaming of the database from the “European” to the Once the pollen data and metadata entry tables had been “Eurasian” Modern Pollen Database. manually completed and checked, these were then uploaded Countries where there are still relatively few or no samples into a Postgres database where a second series of auto- despite being both relatively populous and having an active mated quality control procedures were undertaken. These au- palynological community include Belgium, the Netherlands, tomated checks repeated many of the earlier manual checks, Hungary, Czech Republic, and Slovakia. There are also vir- including ensuring that all open and closed fields were cor- tually no samples from the Balkans. Despite the generally rectly completed and that the taxa names conformed to the excellent coverage over Scandinavia, north-central Sweden database standardised taxa names (the “p_vars” table). In ad- remains poorly sampled, a feature that is also reflected in dition, it was also necessary to manually standardise worker the lack of fossil pollen data from this area in the EPD. Further east, the distribution of samples tends to be best in https://doi.org/10.5194/essd-12-2423-2020 Earth Syst. Sci. Data, 12, 2423–2445, 2020 2432 B. A. S. Davis et al.: The Eurasian Modern Pollen Database (EMPD), version 2 Figure 1. A flow diagram showing the data processing and quality control steps taken in constructing the EMPD2 database. the more populous regions and those with better transport Mediterranean scrub and temperate forests and the western infrastructure. Notable areas across northern Eurasia where range of the boreal forest/taiga and tundra. Less well sam- we still lack samples include the steppes of Ukraine and pled are the temperate shrub and grasslands and deserts of Kazakhstan and the Central Siberian Plateau. Further south, the Central Asian steppe, and the eastern range of the boreal most of China and Mongolia are well covered by the Chi- forest/taiga and tundra. Again, the Chinese Pollen Database nese Pollen Database (now partly released by Herzschuh et (Herzschuh et al., 2019) covers much of the montane biomes al., 2019), and as mentioned earlier, there are efforts in In- of the Himalayas and Tian Shan, the grasslands and deserts dia to improve data coverage in this region. A more diffi- of the Gobi area and Mongolia, and temperate and tropical cult problem is the lack of samples from many of the Central forest biomes of East Asia. Asian countries including Turkmenistan, Uzbekistan, Tajik- While a conventional map such as Fig. 5a can show how istan, Afghanistan, and to some extent Pakistan, where access samples are distributed across different biomes in geograph- for scientists is currently difficult or hazardous, and where ical space, it does not show how well those samples are dis- there are few locally trained scientists. The lack of modern tributed in climate space. Large areas of Earth may have the pollen data from these regions is also reflected in a lack of same or similar climate, and the distribution of samples in fossil pollen studies from these countries. conventional space does not necessarily equate to how well climate space has been sampled. Climate space is important 3.2 Altitudinal sampling because pollen-based climate reconstructions depend on the use of modern pollen calibration datasets that fully sample The representativeness of the sample coverage in the vertical the available climate space associated with any particular spatial domain is not easily discernible from a standard two- vegetation type. Figure 5b shows the same information as dimensional map presented in Fig. 3. Vertical climate and Fig. 5a, but this time in climate space. This indicates that the vegetation gradients are much steeper than horizontal gra- EMPD2 samples appear better distributed in climate space dients, and hilly and mountainous terrain typically holds a than geographical space, but that there are fewer samples to greater variety of vegetation and climate types than can be represent the more extreme climates found at the edges of shown on a continental-scale map. We make a better attempt the modern climate space (such as tundra, deserts, and xeric to show this by plotting the distribution of samples by alti- scrublands). This is shown more clearly in Fig. 6b, where tude on a hypsometric (or cumulative frequency) curve for the Euclidean distance is calculated between the climate of the Palearctic study region (Fig. 4). This shows that the num- each of the pollen samples in EMPD2 and all of the avail- ber of samples generally follows the proportion of land area able climate space of the Palearctic region. This was done represented at each elevation, with more samples at lower al- using mean annual temperature and precipitation from the titude, but there is still the presence of samples as the altitude WorldClim2 modern climatology (Fick and Hijmans, 2017), gets higher. Data coverage has improved in particular in the normalised to make the different scales comparable. The cli- 500–2500 m range between EMPD1 and EMPD2. The upper mate of the pollen site were assigned according to the nearest part of the altitudinal range above 3500 m is dominated by grid point within the 30 second (approximately 1km2 ) resolu- the Himalayas and the Tibetan Plateau, which is covered by tion of the WorldClim2 grid, whilst the climate of the region the Chinese Pollen Database (Herzschuh et al., 2019). was taken from the grid itself. The darker regions around the edges of the climate space show where in climate space the 3.3 Climate and vegetation sampling EMPD2 still lacks representative samples. These poorly rep- resented climates are then shown in physical space in Fig. 6a. The distribution of the EMPD2 samples across the vegeta- This indicates poor representation in the North African and tion biomes of the region (from Olson et al., 2001) is shown Persian deserts, which are outside the Palearctic study region, in Fig. 4. Biomes that are well sampled within the Palearctic but also areas within the Palearctic region including the Cen- region include most of those that occur in Europe, namely Earth Syst. Sci. Data, 12, 2423–2445, 2020 https://doi.org/10.5194/essd-12-2423-2020 B. A. S. Davis et al.: The Eurasian Modern Pollen Database (EMPD), version 2 2433 tation analogues of fossil pollen samples. The database con- tinues to increase in size through a mixture of newly sub- mitted samples from old studies that predate EMPD1 and more recent studies that have occurred since EMPD1 was first made available. It is still likely that older data will con- tinue to be submitted to the database, especially as it becomes better known, but it is unlikely that the database will continue to grow at the present rate given that much of the available older data are now expected to have been submitted. How- ever, surface sample work has traditionally been less likely to be published in international journals, often confined to Mas- ters or PhD theses or other grey literature, and the amount of data in existence may therefore be difficult to estimate. To help promote access and use of the EMPD, we have created an online data viewer https://empd2.github.io (last access: 20 January 2020) (Fig. 7) (Sommer et al., 2020). This allows the database to be viewed using an intuitive clickable map that displays the location of each sample, associated metadata, and a plot of the pollen data themselves. It is also possible to download the data associated with a sample and to make suggested corrections. Other options allow the user to select subsets of the database to be viewed, for instance associated with particular individuals, projects, or research groups. The EMPD viewer allows access to the database in an intuitive way without requiring any particular computer expertise. This has been very important in not only allowing the casual user to view and access the data in the database, but also in allowing the data submitters to view their data as they exist in the database after they have been processed, providing a further quality control check. The data viewer is open source and can be adapted for other uses. The EMPD data viewer is embedded in a web framework that is based on the version control system GitHub, where users and data contributors can transparently submit new data or raise issues with the existing data. These can then be re- viewed in an open discussion with the database managers. This framework allows ongoing development of the EMPD in the future, and the usage of a free version control system Figure 2. A comparison of the number of samples in EMPD ver- sions 1 and 2, by country. Countries with only small numbers of additionally ensures full transparency, stability, and main- samples are listed at the bottom; values in brackets indicate new tainability of access to the data, independent of funding and samples in EMPD2. changing collaborations. As well as simply adding more samples as they are submit- ted, we hope that the future development of the EMPD will tral Asian steppe and more mountainous areas of the Central also be more targeted. It is clear that although sample cover- Siberian Plateau and Siberia east of Yakutsk (130◦ E). age is much improved in EMPD2, gaps still exist in the data coverage for Eurasia that would be useful to fill (Figs. 4–6). One way to do this is to encourage fieldwork to collect sam- 4 Discussion ples from these data-poor regions. This approach however is expensive, since the reason why many of these areas remain The increase in size of the EMPD in version EMPD2 has unsampled is precisely because of their remoteness and the greatly improved the coverage of modern pollen samples difficulty and expense involved in accessing them. An alter- across Eurasia in relation to geographical, vegetation, and native that has not been widely exploited is to analyse soil climate space. This will make it possible to create more accu- and sediment samples gathered as a result of fieldwork expe- rate reconstructions of past land cover and climate given the ditions organised with a different objective in mind. We hope commensurate improvements in available climate and vege- that by demonstrating the important sampling gaps in the https://doi.org/10.5194/essd-12-2423-2020 Earth Syst. Sci. Data, 12, 2423–2445, 2020 2434 B. A. S. Davis et al.: The Eurasian Modern Pollen Database (EMPD), version 2 Figure 3. Map of samples included in EMPD versions 1 and 2 and two other datasets (see text). or if a data contributor makes a significant contribution to the analysis of the data or to the interpretation of results. For large-scale studies using many EMPD/EPD records, con- tacting all contributors or making them co-authors will not be practical, possible, or reasonable. Under no circumstance should authorship be attributed to data contributors, individ- ually or collectively, without their explicit consent. In all cases, any use of EMPD data should include the fol- lowing or similar text in the acknowledgements: “Pollen data were extracted from the Eurasian Modern Pollen Database (part of the European Pollen Database), and the work of the data contributors and the EMPD/EPD community is grate- fully acknowledged.” Upon publication, please send to the EMPD/EPD a copy of the published work or a link to the electronic resource. Your assistance helps document the us- age of the database, which is critical to ensure continued sup- Figure 4. Distribution of samples by altitude for the Palearctic re- port from funders and contributors. gion (compared to land area at each altitude). 6 Data availability database it will encourage individuals and research groups to consider fieldwork and data analysis in these underrepre- The EMPD is available at sented regions. https://doi.org/10.1594/PANGAEA.909130 (Chevalier et al., 2019). The data are available as (1) an Ex- 5 Ethical statement and how to acknowledge the cel spreadsheet, (2) a PostgreSQL dump, and (3) a database SQLite3 portable database format. The data can also be viewed online using an interactive map-based viewer Users of the database are expected to follow the guide- at https://empd2.github.io/?branch=master (last access: lines of the EPD. These state that normal ethics apply 20 January 2020). to co-authorship of scientific publications. Palaeoecological datasets are labour intensive and complex, they take many 7 Conclusions years to generate, and they may have additional attributes and metadata not captured in the EMPD/EPD. Users of data The EMPD remains the only public, quality-controlled, and stored in the EMPD/EPD should consider inviting the origi- standardised database of modern pollen samples for the nal data contributor of any resultant publications if that con- Eurasian region. This paper describes a recent update to the tributor’s data are a major portion of the dataset analysed, EMPD in which the database has increased almost 60 % in Earth Syst. Sci. Data, 12, 2423–2445, 2020 https://doi.org/10.5194/essd-12-2423-2020 B. A. S. Davis et al.: The Eurasian Modern Pollen Database (EMPD), version 2 2435 Figure 5. (a) Biome map and sample locations. (b) Biomes and samples in climate space. Biome data from Olson et al. (2001) size, so that it now contains data on 8663 modern pollen prove access to, and participation in, the EMPD, as well as samples. This reflects an expansion in spatial coverage across quality control. We expect the EMPD to continue to grow in northern and eastern Asia, which has prompted a change in the future, although probably at a slower rate given that most the name of the database from the European to the Eurasian of the previously published “heritage” data have now been Modern Pollen Database. The improvement in spatial cov- incorporated. At present the EMPD remains associated with, erage has increased the number of vegetation and climate but physically independent of, the EPD. It is also subject to analogues for fossil pollen samples in the region that will only periodic updates. In future we expect both the EPD and directly improve reconstructions of past vegetation and cli- EMPD to become fully incorporated into the global Neotoma mate. However, areas of poor data coverage still exist, par- Palaeoecological Database, which will provide seamless in- ticularly in the more remote regions of central and northern tegration of the fossil and modern data, whilst also allowing Asia and the Middle East. Development of a new map-based continual updates using Neotoma data management tools. online data viewer for the database is already helping im- https://doi.org/10.5194/essd-12-2423-2020 Earth Syst. Sci. Data, 12, 2423–2445, 2020 2436 B. A. S. Davis et al.: The Eurasian Modern Pollen Database (EMPD), version 2 Figure 6. (a) The Euclidian distance between the climate of each modern pollen sample location (as shown in Fig. 3) and the climate of the entire Palearctic region. (b) The same as (a) but shown in climate space. Note that for clarity the values < 0.05 are shown by dark grey in (a), but white in (b). The darker the brown shading, the less well that climate is represented amongst the samples. The climate of each pollen site was assigned according to the nearest grid point within the 30 s (approximately 1 km2 ) resolution of the WorldClim2 grid, whilst the climate of the region was taken from the grid itself. Earth Syst. Sci. Data, 12, 2423–2445, 2020 https://doi.org/10.5194/essd-12-2423-2020 B. A. S. Davis et al.: The Eurasian Modern Pollen Database (EMPD), version 2 2437 Figure 7. Screen grab of the EMPD online data viewer (available at https://empd2.github.io, last access: 20 January 2020). Author contributions. BASD wrote the manuscript with input Review statement. This paper was edited by Thomas Blunier and from all of the authors. BASD, MC, and PS designed and imple- reviewed by two anonymous referees. mented the database and data viewer. BASD, MC, PS, MZ, WF, LNP, AM, and VC all helped with data processing. All of the re- maining authors contributed pollen sample data and were involved in the original collection, preparation, identification, and counting of these data. References Abbate, G.: Studio delle tipologie fitosociologiche del Monte So- ratte Lazio e loro contributo nella definizione fitogeografica dei Competing interests. The authors declare that they have no con- complessi vegetazionali centro-appenninici, Consiglio Nazionale flict of interest. delle Ricerche, 1981. Åkesson, C., Nielsen, A. B., Broström, A., Persson, T., Gail- lard, M.-J., and Berglund, B. E.: From landscape de- Acknowledgements. The EMPD includes data obtained from scription to quantification: A new generation of recon- the Neotoma Palaeoecology Database and the European Pollen structions provides new perspectives on Holocene regional Database. 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